Module java.base
Package java.util

Class LinkedHashMap<K,V>

java.lang.Object
java.util.AbstractMap<K,V>
java.util.HashMap<K,V>
java.util.LinkedHashMap<K,V>
Type Parameters:
K - the type of keys maintained by this map
V - the type of mapped values
All Implemented Interfaces:
Serializable, Cloneable, Map<K,V>, SequencedMap<K,V>

public class LinkedHashMap<K,V> extends HashMap<K,V> implements SequencedMap<K,V>

Hash table and linked list implementation of the Map interface, with well-defined encounter order. This implementation differs from HashMap in that it maintains a doubly-linked list running through all of its entries. This linked list defines the encounter order (the order of iteration), which is normally the order in which keys were inserted into the map (insertion-order). The least recently inserted entry (the eldest) is first, and the youngest entry is last. Note that encounter order is not affected if a key is re-inserted into the map with the put method. (A key k is reinserted into a map m if m.put(k, v) is invoked when m.containsKey(k) would return true immediately prior to the invocation.) The reverse-ordered view of this map is in the opposite order, with the youngest entry appearing first and the eldest entry appearing last. The encounter order of entries already in the map can be changed by using the putFirst and putLast methods.

This implementation spares its clients from the unspecified, generally chaotic ordering provided by HashMap (and Hashtable), without incurring the increased cost associated with TreeMap. It can be used to produce a copy of a map that has the same order as the original, regardless of the original map's implementation:


     void foo(Map<String, Integer> m) {
         Map<String, Integer> copy = new LinkedHashMap<>(m);
         ...
     }
 
This technique is particularly useful if a module takes a map on input, copies it, and later returns results whose order is determined by that of the copy. (Clients generally appreciate having things returned in the same order they were presented.)

A special constructor is provided to create a linked hash map whose encounter order is the order in which its entries were last accessed, from least-recently accessed to most-recently (access-order). This kind of map is well-suited to building LRU caches. Invoking the put, putIfAbsent, get, getOrDefault, compute, computeIfAbsent, computeIfPresent, or merge methods results in an access to the corresponding entry (assuming it exists after the invocation completes). The replace methods only result in an access of the entry if the value is replaced. The putAll method generates one entry access for each mapping in the specified map, in the order that key-value mappings are provided by the specified map's entry set iterator. No other methods generate entry accesses. Invoking these methods on the reversed view generates accesses to entries on the backing map. Note that in the reversed view, an access to an entry moves it first in encounter order. Explicit-positioning methods such as putFirst or lastEntry, whether on the map or on its reverse-ordered view, perform the positioning operation and do not generate entry accesses. Operations on the keySet, values, and entrySet views or on their sequenced counterparts do not affect the encounter order of the backing map.

The removeEldestEntry(Map.Entry) method may be overridden to impose a policy for removing stale mappings automatically when new mappings are added to the map. Alternatively, since the "eldest" entry is the first entry in encounter order, programs can inspect and remove stale mappings through use of the firstEntry and pollFirstEntry methods.

This class provides all of the optional Map and SequencedMap operations, and it permits null elements. Like HashMap, it provides constant-time performance for the basic operations (add, contains and remove), assuming the hash function disperses elements properly among the buckets. Performance is likely to be just slightly below that of HashMap, due to the added expense of maintaining the linked list, with one exception: Iteration over the collection-views of a LinkedHashMap requires time proportional to the size of the map, regardless of its capacity. Iteration over a HashMap is likely to be more expensive, requiring time proportional to its capacity.

A linked hash map has two parameters that affect its performance: initial capacity and load factor. They are defined precisely as for HashMap. Note, however, that the penalty for choosing an excessively high value for initial capacity is less severe for this class than for HashMap, as iteration times for this class are unaffected by capacity.

Note that this implementation is not synchronized. If multiple threads access a linked hash map concurrently, and at least one of the threads modifies the map structurally, it must be synchronized externally. This is typically accomplished by synchronizing on some object that naturally encapsulates the map. If no such object exists, the map should be "wrapped" using the Collections.synchronizedMap method. This is best done at creation time, to prevent accidental unsynchronized access to the map:

   Map m = Collections.synchronizedMap(new LinkedHashMap(...));
A structural modification is any operation that adds or deletes one or more mappings or, in the case of access-ordered linked hash maps, affects iteration order. In insertion-ordered linked hash maps, merely changing the value associated with a key that is already contained in the map is not a structural modification. In access-ordered linked hash maps, merely querying the map with get is a structural modification. )

The iterators returned by the iterator method of the collections returned by all of this class's collection view methods are fail-fast: if the map is structurally modified at any time after the iterator is created, in any way except through the iterator's own remove method, the iterator will throw a ConcurrentModificationException. Thus, in the face of concurrent modification, the iterator fails quickly and cleanly, rather than risking arbitrary, non-deterministic behavior at an undetermined time in the future.

Note that the fail-fast behavior of an iterator cannot be guaranteed as it is, generally speaking, impossible to make any hard guarantees in the presence of unsynchronized concurrent modification. Fail-fast iterators throw ConcurrentModificationException on a best-effort basis. Therefore, it would be wrong to write a program that depended on this exception for its correctness: the fail-fast behavior of iterators should be used only to detect bugs.

The spliterators returned by the spliterator method of the collections returned by all of this class's collection view methods are late-binding, fail-fast, and additionally report Spliterator.ORDERED.

This class is a member of the Java Collections Framework.

Implementation Note:
The spliterators returned by the spliterator method of the collections returned by all of this class's collection view methods are created from the iterators of the corresponding collections.
Since:
1.4
See Also: